Hot Gas-Guided Component of a Turbomachine

ABSTRACT

A The hot-gas conducting component for a flow machine has a nickel-base wrought alloy as structural material and a hot gas-side lining made from the group of iron-chromium-aluminum-yttrium alloys and a flow machine having a component of this type.

The present invention is directed to a hot-gas conducting component of a flow machine according to the preamble of claim 1 and to a flow machine with a component of this type.

Hot-gas conducting components of flow machines such as, e.g., combustion chamber linings, turbine inlet housings, hot gas ducts, and turbine blading must maintain their functionality under extreme thermal and mechanical loads. The components are continually exposed to oxidation and corrosion, and temperatures often exceed 1000° C. At the same time, compressed cooling air is only available to a limited extent.

With the exception of turbine blading, hot-gas conducting components which are exposed to high thermal loading but not to extreme mechanical loading are conventionally produced from solid-solution hardened, nickel-base wrought alloys. Alloys of this type are characterized by a high resistance to heat. However, nickel-base wrought alloys have the disadvantage they are moderately oxidizability. To mitigate this disadvantage, hot-gas conducting components are usually provided with a ceramic-based coating on the hot gas side. But ceramic coatings of this type are costly to produce and apply.

It is the object of the present invention to provide a hot-gas conducting component of a flow machine with a hot gas-side lining which is improved over known ceramic coatings and to provide a flow machine with a component of this kind.

This object is met by a hot-gas conducting component having the features of claim 1 and by a flow machine having the features of claim 7.

According to the invention, a hot-gas conducting component of a flow machine has, as a structural material and, therefore, as a supporting construction, a solid-solution hardened nickel-base wrought alloy and a hot gas-side lining made from the group of iron-chromium-aluminum-yttrium alloys.

Iron-chromium-aluminum-yttrium alloys, abbreviated as FeCrAlY alloys, have a very good resistance to oxidation. The temperature limit from the view point of the oxidation criterion is about 1200° C. Therefore, the operating temperature and stability of the hot-gas conducting components can be increased without the life of the structural material being disproportionately shortened by oxidation. The heat resistance of the FeCrAlY alloys can be called moderate. The moderate material properties of the two alloys—nickel-base wrought alloys, or Ni-base alloys for short, show a moderate resistance to oxidation, and FeCrAlY alloys have a moderate resistance to heat—are overcome by the combination according to the invention and by the construction according to the invention of the hot-gas conducting component due to the excellent resistance to oxidation and heat of the other respective alloy. In other words, the operating temperature and stability of the hot-gas conducting component according to the invention are improved by making effective use of the respective excellent property of the alloys.

In an embodiment example, the hot gas-side lining is made from an aluchrom-yttrium-hafnium alloy. In particular, the cyclic oxidation resistance of the hot gas-side lining can be increased by the active elements yttrium and hafnium.

The FeCrAlY alloy preferably has iron as a base element and comprises 16% to 24% chromium, 3% to 9% aluminum, 0.02% to 0.2% yttrium, up to 0.1% hafnium, up to 0.1% zirconium, and up to 0.1% metals from the group of rare earths, particularly lanthanides.

The hot gas-side lining can be applied by means of high-temperature soldering, welding, or cladding, particularly roll bonding cladding.

In an embodiment example, the structural material of the hot-gas conducting component is sandwiched between the hot gas-side lining and a cooling air-side coating which is preferably made of an alloy from the group of nickel-cobalt-iron-chromium-aluminum-yttrium (MCrAlY) alloys.

A flow machine according to the invention has at least one hot-gas conducting component which has a structural material comprising a solid-solution hardened nickel-base wrought alloy which is provided with a hot gas-side lining made from the group of iron-chromium-aluminum-yttrium alloys.

Other advantageous embodiment examples of the invention are indicated in additional dependent claims.

Preferred embodiment examples of the invention are described more fully in the following.

According to the invention, a hot-gas conducting component of a flow machine, particularly a gas turbine, is constructed as a composite material comprising a solid-solution hardened nickel (Ni) base wrought alloy and an oxidation-resistant ferrific iron base alloy, particularly an FeCrAlY alloy. The Ni base wrought alloy forms the supporting construction and structural material of the component, and the FeCrAlY alloy is applied to the structural material as a hot gas-side lining. Within the meaning of the invention, “hot gas side” means that the lining is applied to an inner surface of the component facing the hot gases. In a corresponding manner, “cooling air side” within the meaning of the invention means a coating is arranged on an outer surface of the component facing the cooling air.

For example, a hot-gas conducting component of a gas turbine is the Y-branch pipe which serves as a hot-gas guiding duct between the combustion chambers and the turbine blading and guides the hot gases from the combustion chamber to the first turbine stage. Other hot-gas conducting components are, for example, combustion chamber linings and turbine inlet housings.

A preferred material from the group of FeCrAlY alloys is an aluminum-chromium-yttrium-hafnium alloy, abbreviated aluchrom-YHf alloy.

Aside from the active element yttrium (Y) and hafnium (Hf), additional active elements such as, e.g., zirconium (Zr), can be mixed in with the FeCrAlY alloy to increase the cyclic oxidation resistance.

An FeCrAlY alloy having iron (Fe) as base element and comprising 16% to 24% chromium (Cr), 3% to 9% aluminum (Al), 0.02% to 0.2% yttrium (Y), up to 0.1% hafnium (Hf), up to 0.1% zirconium (Zr), and up to 0.1% metals from the group of rare earths (RE) is particularly preferable. Lanthanides or lanthanoids (La), e.g., cerium (Ce), praseodymium (Pr), neodymium (Nd), and promethium (Pm), are mentioned in particular as examples from the group of rare earths.

The FeCrAlY alloys are applied to the structural material by means of known methods of high-temperature soldering, welding, or cladding and roll bonding cladding. To prevent interdiffusion between the structural material and the lining, a diffusion barrier, e.g., based on the Al—O—N system, can be used.

The use of the FeCrAlY alloy as lining is not limited to the hot gas side of the components; rather, it is also conceivable to construct the hot-gas conducting component in a sandwich-type manner. In so doing, the structural material of solid-solution hardened Ni base wrought alloy constitutes the supporting structural core which is arranged between a hot gas-side lining and a cooling air-side coating based on the above-described FeCrAlY alloys.

The disclosure relates to a hot-gas conducting component for a flow machine with a nickel base wrought alloy as structural material and a hot gas-side lining from the group of iron-chromium-aluminum-yttrium alloys and to a flow machine with a component of this type. 

1-8. (canceled)
 9. A hot-gas conducting component of a flow machine comprising a solid-solution hardened nickel-base wrought alloy as structural material; a hot gas-side lining made from an alloy selected from the group of iron-chromium-aluminum-yttrium alloys.
 10. The hot-gas conducting component according to claim 9, wherein the hot gas-side lining is made from an aluchrom-yttrium-hafnium alloy.
 11. The hot-gas conducting component according to claim 9, wherein the iron-chromium-aluminum-yttrium alloy comprises iron as a base element and comprises 16% to 24% chromium, 3% to 9% aluminum, 0.02% to 0.2% yttrium, up to 0.1% hafnium, up to 0.1% zirconium, and up to 0.1% metals from the group of rare earths, particularly lanthanides.
 12. The hot-gas conducting component according to claim 10, wherein the iron-chromium-aluminum-yttrium alloy comprises iron as a base element and comprises 16% to 24% chromium, 3% to 9% aluminum, 0.02% to 0.2% yttrium, up to 0.1% hafnium, up to 0.1% zirconium, and up to 0.1% metals from the group of rare earths, particularly lanthanides.
 13. The hot-gas conducting component according to claim 11, whereby said rare earth metal is selected from lanthanides.
 14. The hot-gas conducting component according to claim 10, whereby said rare earth metal is selected from lanthanides.
 15. The hot-gas conducting component according to claim 9, wherein said hot gas-side lining is applied by means of high-temperature soldering, welding, or cladding.
 16. The hot-gas conducting component according to claim 9, additionally comprising a diffusion barrier between said structural material and said lining.
 17. The hot-gas conducting component according to claim 9, additionally comprising a cooling air-side coating applied to aid structural material.
 18. The hot-gas conducting component according to claim 17, wherein said cooling air-side coating is an alloy selected from the group of MCrAlY alloys.
 19. A flow machine having a hot-gas conducting component according to claim
 9. 